Input apparatus and control method for input apparatus

ABSTRACT

An input apparatus has a touch sensor  11  configured to detect a touch input, a piezoelectric element  12  mounted on the touch sensor  11 , and a control unit  15  configured to detect a pressure load on a touch face  11   a  of the touch sensor  11  based on an output signal of the piezoelectric element  12  and, when the pressure load detected satisfies a standard to provide a tactile sensation, to drive the piezoelectric element  12  such that the tactile sensation is provided to an object pressing the touch face  11   a.

CROSS REFERENCE TO RELATED APPLICATION

This application is a Continuation Application of U.S. patentapplication Ser. No. 13/392,867, filed Feb. 27, 2012, which is the U.S.National Phase of International Application No. PCT/JP2010/005277 filedAug. 26, 2010, which claims priority to and the benefit of JapanesePatent Application No. 2009-197132 filed on Aug. 27, 2009, the entirecontents of which are incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to an input apparatus having a touchsensor and a control method for an input apparatus.

BACKGROUND ART

In recent years, input apparatus such as operation units, switches andthe like having touch sensors such as touch panels, touch switches andthe like to receive input operations by users have been widely used formobile terminals such as mobile phones, information equipment such ascalculators and ticket vending machines, home electric appliances suchas microwaves, TV sets and lighting equipment, industrial equipment (FAequipment) and the like.

There are known a variety of types of those touch sensors, such as aresistive film type, a capacitive type, an optical type and the like.However, touch sensors of these types receive a touch input by a fingeror a stylus pen and, unlike push-button switches, the touch sensorsthemselves are not physically displaced even when being touched.

Since the touch sensors themselves are not physically displaced whentouched, an operator cannot obtain feedback to an input even though thetouch input is received. As a result, the operator is likely to inputerroneously by touching the same spot multiple times, which may bestressful for the operator.

As methods to prevent such erroneous inputs, there are known methodsallowing to visually or aurally confirm the input operation uponreception of the touch input by, for example, generating sounds orchanging a display state such as color of input object of input buttonand the like graphically depicted on a display unit.

However, such auditory feedback may be difficult to be confirmed in anoisy environment and is not applicable when the equipment being used isin a silent mode. In addition, in using such visual feedback, when theoperator is inputting by the finger, if the input object displayed onthe display unit is small, the operator may not be able to confirm thechange in the display state, as a view of the input object is blocked bythe finger.

There is also suggested a feedback method relying on neither theauditory- nor visual sensation but instead generating a tactilesensation at operator's fingertip by vibrating the touch sensor when thetouch sensor receives an input (for example, see Patent Documents 1, 2).

RELATED ART DOCUMENTS Patent Documents

Patent Document 1: Japanese Patent Laid-Open No. 2003-288158

Patent Document 2: Japanese Patent Laid-Open No. 2008-130055

SUMMARY OF DISCLOSURE Technical Problem

The techniques disclosed in the above Patent Documents 1 and 2, however,merely vibrate the touch sensor when the touch sensor receives an input.Therefore, in using the input apparatus having the button switch such asa mechanical push-button switch (push-type button switch) graphicallydepicted on the touch sensor having a low threshold to receive theinput, a tactile sensation is provided when the finger or the likelightly contacts (touches) the touch sensor. It may trigger erroneousoperations by responding to an unintentional motion (touch) before theoperator pushes the touch sensor and bring a feeling of strangeness tothe operator upon such an unintentional motion (touch). Here, thethreshold for the touch sensor to receive a touch input is a thresholdat which the touch sensor responds. For example, for a touch sensor ofthe resistive film type, the threshold is a threshold of a pressure atwhich an upper conductive film is contacted to a lower conductive filmand, for a touch sensor of the capacitive type, the threshold is athreshold for detection of an electric signal by contact.

In order to clear such a disadvantage, the applicant has developed aninput apparatus which detects the pressure load of touch to the touchface of the touch sensor and, when the detected load reaches apredetermined threshold to provide the tactile sensation, vibrates thetouch face of the touch sensor such that the tactile sensation isprovided to a pressing object such as the finger and the like.

According to this input apparatus, since the tactile sensation isprovided when the operator pushes the touch face and the pressure loadreaches the predetermined threshold, it is possible to allow theoperator to perceive reception of an input while reliably preventingerroneous operations triggered by the unintentional touch describedabove and the feeling of strangeness.

Incidentally, the input apparatus needs a load sensor to detect thepressure load on the touch sensor and an actuator to vibrate the touchsensor in addition to basic components such as the touch sensor and acontrol unit. This leads to increase in the number of components andcost as well as a size of the apparatus to retain necessary space forthe components. Therefore, there is room for improvement inimplementation of the input apparatus described above, in terms of thecost and downsizing of the input apparatus.

An object of the present disclosure, in consideration of such issues, isto provide an input apparatus and a control method of the inputapparatus appropriately configured to enable cost reduction anddownsizing

Solution to Problem

In order to achieve the above object, an input apparatus according to afirst aspect of the present disclosure includes:

a touch sensor configured to detect a touch input;

a piezoelectric element mounted on the touch sensor; and

a control unit configured to detect a pressure load on a touch face ofthe touch sensor based on an output signal of the piezoelectric elementand, when the pressure load detected satisfies a standard to provide atactile sensation, to drive the piezoelectric element such that thetactile sensation is provided to an object pressing the touch face.

A second aspect of the present disclosure is the input apparatusaccording to the first aspect, wherein the piezoelectric element has oneend mounted on the touch sensor and the other end opened.

Moreover, in order to achieve the above object, a control method of aninput apparatus according to a third aspect of the present disclosureincluding a touch sensor configured to detect a touch input and apiezoelectric element having one end mounted on the touch sensor and theother end opened, includes the step of: detecting a pressure load on atouch face of the touch sensor based on an output signal of thepiezoelectric element and, when the pressure load detected satisfies astandard to provide a tactile sensation, driving the piezoelectricelement such that the tactile sensation is provided to an objectpressing the touch face.

Effect of the Disclosure

The input apparatus according to the present disclosure, utilizingdirect piezoelectric effect and converse piezoelectric effect of thepiezoelectric element, uses the piezoelectric element as a load sensorto detect the pressure load on the touch face of the touch sensor and asan actuator to vibrate the touch face, thereby sharing one component fora plurality of functions. It is thus possible to reduce the number ofcomponents and the cost as well as to save space for the componentsachieving downsizing of the apparatus.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a functional block diagram illustrating a schematicconfiguration of an input apparatus according to one embodiment of thepresent disclosure;

FIG. 2 illustrates a cross-sectional view of a main section and a planeview of the main section that illustrate an exemplary housing structureof a touch sensor, piezoelectric elements and a display unit illustratedin FIG. 1; and

FIG. 3 is a flowchart illustrating a schematic operation of the inputapparatus illustrated in FIG. 1.

DESCRIPTION OF EMBODIMENT

An embodiment of the present disclosure will be described with referenceto the accompanying drawings.

FIG. 1 is a functional block diagram illustrating a schematicconfiguration of an input apparatus according to one embodiment of thepresent disclosure. The input apparatus has a touch sensor 11, apiezoelectric element 12, a display unit 13, and a control unit 14 tocontrol an operation of each unit.

Under control of the control unit 14, the touch sensor 11 detects atouch input to a touch face of the touch sensor 11 by a pressing object,such as a finger and the like, and provides the control unit 14 withposition information of a touch position. The touch sensor 11 may be ofa known type, such as a resistive film type, a capacitive type, anoptical type and the like, and disposed on the display unit 13.

The piezoelectric element 12 is mounted on the touch sensor 11. Undercontrol of the control unit 14, the piezoelectric element 12 isactivated in one of a load detection mode to detect the pressure load onthe touch face of the touch sensor 11 by utilizing direct piezoelectriceffect or a tactile sensation providing mode to vibrate the touch faceof the touch sensor 11 by utilizing converse piezoelectric effect. Inthe load detection mode, the piezoelectric element 12 supplies thecontrol unit 14 with an output signal corresponding to the pressure loadon the touch face of the touch sensor 11. In the tactile sensationproviding mode, the piezoelectric element 12 vibrates the touch face ofthe touch sensor 11 based on a drive signal supplied from the controlunit 14 such that a predetermined tactile sensation corresponding to thedrive signal is provided to the pressing object pressing the touch face.

Under control of the control unit 14, the display unit 13 displays aninput object of an input button and the like such as a push-buttonswitch (push-type button switch) and may be constituted by using, forexample, a liquid crystal display panel, an organic EL display panel andthe like. The touch input to the input object displayed on the displayunit 13 is detected by the control unit 14 based on the positioninformation output from the touch sensor 11.

The control unit 14 may be, for example, a CPU and the like and controlsthe operation of each unit based on the position information from thetouch sensor 11, display information for the display unit 13, the outputsignal corresponding to the pressure load obtained from thepiezoelectric element 12 in the load detection mode, and the like.

FIG. 2 illustrates an exemplary housing structure of the touch sensor11, the piezoelectric elements 12 and the display unit 13 illustrated inFIG. 1; FIG. 2(a) is a cross-sectional view of a main section, and FIG.2(b) is a plane view of the main section. The display unit 13 iscontained in a housing 21. The touch sensor 11 is disposed on thedisplay unit 13 via insulators 22 made of elastic members. According tothe present embodiment, the touch sensor 11 is disposed on the displayunit 13 via the insulators 22 arranged at four corners outside a displayarea A of the display unit 13 illustrated by a chain double-dashed linein FIG. 2(b).

The housing 21 is provided with an upper cover 23 covering a surfacearea of the touch sensor 11 outside the display area of the display unit13. An insulator 24 for dust-proof made of elastic member is arrangedbetween the upper cover 23 and the touch sensor 11.

The touch sensor 11 illustrated in FIG. 2 may have, for example, asurface member having a touch face 11 a and made of a transparent filmor the glass, and a rear face member made of the glass or acryl. Thetouch sensor 11 is designed such that, when the touch face 11 a ispressed down via the insulator 24, a pushed part is slightly bent(strained) in accordance with pressure and thereby an entire touchsensor 11 including the rear face member is slightly bent.

Each piezoelectric element 12 is provided on the rear face of the touchsensor 11 at a position covered by the upper cover 23 and close to oneor a plurality of peripheries, here it is three peripheries. These threepiezoelectric elements 12 are connected to the control unit 14 inparallel. Each of the piezoelectric elements 12 detects the pressureload on the touch face 11 a of the touch sensor 11 and vibrates thetouch sensor 11 such that the tactile sensation is provided to thepressing object pressing the touch face 11 a. It is to be noted that thehousing 21, the upper cover 23 and the insulator 24 illustrated in FIG.2(a) are omitted in FIG. 2(b).

FIG. 3 is a flowchart of a schematic operation of the input apparatusaccording to the present embodiment. The control unit 14 sets the threepiezoelectric elements 12 in the load detection mode constantly andmonitors the output signals of them (step S301). In addition, thecontrol unit 14 monitors output of the touch sensor 11 and detectswhether the position information of the touch input by the pressingobject (pressing means) such as the finger and the like obtained fromthe touch sensor 11 indicates an input to a position corresponding tothe input object displayed on the display unit 13 (step S302). As aresult, when the position information from the touch sensor 11 indicatesthat it is an input to a position corresponding to the input objectdisplayed on the display unit 13 (in case of “Yes”), a display state,such as color and the like, of the input object on the display unit 13is changed (step S303).

Moreover, the control unit 14 calculates the pressure load on the touchsensor 11 based on the output of the three piezoelectric elements 12 anddetermines whether the pressure load satisfies a standard (for example,1 N) to provide the tactile sensation (step S304). As a result, whendetecting that the pressure load satisfies the standard (in case of“Yes”), the control unit 14 switches the three piezoelectric elements 12from the load detection mode to the tactile sensation providing mode(step S305). Subsequently, the control unit 14 drives the threepiezoelectric elements 12 by supplying (applying) them with respectivepredetermined drive signals. Thereby, the touch sensor 11 is vibratedand provides the tactile sensation to the pressing object touching thetouch face 11 a (step S306). Then, the control unit 14 switches thethree piezoelectric elements 12 back to the load detection mode (stepS307) and calculates the pressure load on the touch sensor 11.

Preferably, at step S304, the pressure load is calculated based on theoutput of the three piezoelectric elements 12, such that approximatelythe same calculation result is obtained when an operator feels nearlythe same pressure sensation (hard feeling, soft feeling and the like) ateach position on the touch face 11 a. Accordingly, the control unit 14calculates the pressure load based on, for example, an average value ofthe output of the three piezoelectric elements, a weighted additionalvalue and the like. Similarly, at the step S306, such the drive signalsare applied to the respective three piezoelectric elements 12 that theoperator preferably obtains nearly the same pressure sensation andnearly the same touch sensation (feeling of texture and the like) ateach position on the touch face 11 a. Therefore, the control unit 14appropriately changes amplitude, a phase and the like in accordance witha position and a location on the touch face 11 a such that anapproximately the same tactile sensation in combination of the pressuresensation and the touch sensation is provided.

At step S304, in addition, the standard of the pressure load to providethe tactile sensation may be appropriately set in accordance with a loadcharacteristic of an intended push-button switch in pressing. Forexample, the standard may be set to be equal to a load at which thetouch sensor 11 responds to the touch input (synchronizing a timing toprovide the tactile sensation with a timing of response to the touchinput by the touch sensor 11) or to be higher than the load at which thetouch sensor 11 responds to the touch input (setting the timing toprovide the tactile sensation later than the timing of response to thetouch input by the touch sensor 11). For example, when the inputapparatus according to the present embodiment is applied to a mobileterminal, it is preferable to set the standard equal to or higher thanthe load at which the touch sensor 11 responds to the touch input(setting the timing to provide the tactile sensation later than thetiming of response to the touch input by the touch sensor 11).Preferably, the standard is set by users as desired such that an elderuser may set it heavier (slower) and a user who often writes messagesmay set it lighter (quicker).

In addition, the tactile sensation provided at step S306 may beappropriately set based on the drive signal applied to the piezoelectricelements 12. For example, in order to provide a click sensation “Cli”,which is obtained when a push-button switch employed by the mobileterminal is pressed, the control unit 14 drives the piezoelectricelements 12 as follows. That is, upon application of the pressure loadsatisfying the standard set forth above, the drive signal, for example,a sine wave with a constant frequency of, for example, 100 Hz to 200 Hz,preferably 170 Hz, for 1 period is applied to the piezoelectric elements12 such that the touch face 11 a is vibrated by approximately 15 μmwhile the pressure load satisfying the standard is applied thereto.Thereby, it is possible to allow the operator to recognize that an inputoperation is completed, by providing a realistic click sensation to theoperator through the pressing object (pressing means) pressing the touchface 11 a of the touch sensor 11. Similarly, in order to provide anotherclick sensation “Click”, which feels harder than the click sensation“Cli”, the control unit 14 applies the drive signal, for example, a sinewave or a square wave with a frequency of, for example, approximately200 Hz to 500 Hz, for 1 period to the piezoelectric elements 12.

As described above, the control unit 14 does not drive the piezoelectricelements 12 until the load applied to the touch sensor 11 calculatedbased on the output of the piezoelectric elements 12 satisfies thestandard to provide the tactile sensation (for example, 1 N). Thereby, atactile sense of the operator is stimulated. Then, when the loaddetected satisfies the standard, the control unit 14 drives thepiezoelectric elements 12 with the predetermined drive signals andvibrates the touch face 11 a. Thereby, the click sensation is providedto the operator by stimulating the touch sense of the operator such thatthe operator recognizes that the input operation is completed.Accordingly, even if the button switch such as the push-button switch(push-type button switch) is graphically depicted on the touch sensor,the operator inputs to the touch sensor 11 feeling the realistic clicksensation similar to that obtained when operating the push-buttonswitch. Thus, the operator may not have the feeling of strangeness.Moreover, since the operator carries out the input operation inconjunction with perception to “have pressed” the touch sensor 11,erroneous input caused by mere tapping is prevented.

In addition, when the standard of the pressure load to provide thetactile sensation is set higher than the load at which the touch sensor11 responds to the touch input (setting the timing to provide thetactile sensation later than the timing of response to the touch inputby the touch sensor 11), the control unit 14 determines an inputposition according to a touch operation to the touch face 11 a andchanges the display state of the input object at a corresponding portionon the display unit 13. Then, when the pressure load on the touch face11 a detected based on the output of the piezoelectric elements 12satisfies the standard to provide the tactile sensation, the controlunit 14 drives the piezoelectric elements 12 to provide the tactilesensation and also execute a predetermined operation (for example,execution and processing of a program corresponding to the object) byconfirming the input position. In this case, the operator confirms thatthe input object is selected, by seeing a change of the display state ofthe input object displayed on the display unit 13. Moreover, since theclick sensation is provided to the operator upon pressing the touch face11 a, the operator recognizes that the input object selected isdetermined (executed). Thereby, it is possible to prevent erroneousinputs by a so-called wandering finger.

In providing the click sensation of the push-button switch as describedabove, the control unit 14, after switching the three piezoelectricelements 12 back in the load detection mode at step S307, switches themin the tactile sensation providing mode when the pressure load fails tosatisfy the standard in releasing as well. Then, the control unit 14drives the three piezoelectric elements 12 with the drive signals, thesame as those in pressing, such that the click sensation described above(a release sensation, at this time) is provided. Thereby, it is possibleto provide a more realistic click sensation bringing the sensation “Cli”in pressing and a sensation “Ck” in releasing. It is to be appreciatedthat the drive signals for the release sensation do not need to be thesame as those for the click sensation.

Here, although the standard of the load to provide the release sensationmay be set to be the same as the standard to provide the click sensationset forth above, it is preferable to set the standard of the load toprovide the release sensation to be 50-80% lower than that to providethe click sensation in pressing. Thereby, timings to provide the tactilesensation are synchronized with timings of sequential inputs when thesame position (input object) is continuously input (tapped), providingthe realistic click sensation without the feeling of strangeness. Thatis, setting the standard of the load to provide the tactile sensation inreleasing to be smaller than that to provide the tactile sensation inpressing enables to prevent the feeling of strangeness. In addition,setting the standard of the load to provide the tactile sensation inreleasing to be approximately 50% or more of that to provide the tactilesensation in pressing contributes to a significant improvement inoperability in the continuous input. Moreover, setting the standard ofthe load to provide the tactile sensation in releasing to beapproximately 80% or less of that to provide the tactile sensation inpressing enables to deal with a faint load change in a holding state inthe continuous input.

In addition, the piezoelectric elements 12 provide not only the clicksensation but also a variety of tactile sensations by changing the drivesignal. For example, in order to provide a soft tactile sensationperceived as a “throbbing” sensation and a “jelly-like” sensation, thedrive signal, for example, a sine wave with a frequency of approximately200 Hz to 500 Hz, for two or three periods is applied. Alternatively, inorder to provide a “vibrating” sensation, the drive signal, for example,a sine wave with a frequency of approximately 200 Hz to 500 Hz, for fouror more periods is applied. Preferably, information on the drive signalsto provide those various tactile sensations is stored in a memory unit(not illustrated) such that the user arbitrarily set the drive signal toprovide a desired tactile sensation. The tactile sensations “Cli”, “Ck”,“Click”, the “throbbing” sensation, the “jelly-like” sensation and the“vibrating” sensation set forth in the present specification aresensations obtained by the operator described in Japanese. Examples ofdrive signals to provide actual tactile sensations are set forth above.

According to the input apparatus of the present embodiment, since thepiezoelectric element 12 is used for a plurality of functions as a loadsensor to detect the pressure load on the touch face 11 a of the touchsensor 11 and as an actuator to vibrate the touch face 11 a, the numberof components and cost are reduced. In addition, reduction of the numberof components saves space for the components, which leads to downsizingof the apparatus.

It is to be understood that the present disclosure is not limited to theembodiment set forth above and various modifications and changes may beimplemented. For example, it is possible to provide any number of thepiezoelectric elements 12 instead of three. In addition, thepiezoelectric element may have a known configuration such as monomorph,unimorph, bimorph and a laminated type, based on a size, vibrationamplitude and the like of the touch sensor 11.

The present disclosure is effectively applicable to an input apparatusin which the touch sensor serves as a touch switch for on/offoperations. Also, the input apparatus according to the presentdisclosure is capable of providing feelings of a multistep switch, suchas a two-step switch (pressed further after pressed), by sequentiallyproviding the click sensation on different standards (loads) while thetouch sensor is being pressed. Thereby, if the input apparatus isapplied to a release button of a camera, for example, a feeling of lockfocus (first step) and a feeling of release (second step) are provided.In addition, in combination with the display unit, the input apparatuschanges a display of a menu screen and the like in a variety of mannersin accordance with the steps of pressing. Moreover, when providing thefeelings of the multistep switch, it is possible to change the drivesignal to vibrate the touch face at each step in order to provide adifferent click sensation at each step.

According to the present disclosure, the input apparatus drives thepiezoelectric element when the pressure load detected based on theoutput of the piezoelectric element satisfies a standard to provide thetactile sensation. Here, “when the pressure load detected based on theoutput of the piezoelectric element satisfies the standard to providethe tactile sensation” may include either “when the pressure loaddetected reaches a standard value to provide the tactile sensation”,“when the pressure load detected exceeds the standard value to providethe tactile sensation”, or “when the standard value to provide thetactile sensation is detected based on the output of the piezoelectricelement”.

REFERENCE SIGNS LIST

-   11 touch sensor-   11 a touch face-   12 piezoelectric element-   13 display unit-   14 control unit-   21 housing-   22 insulator-   23 upper cover-   24 insulator

1. An input apparatus comprising: a touch sensor configured to detect atouch input; a piezoelectric element mounted on the touch sensor; and acontrol unit configured to detect a pressure load on a touch face of thetouch sensor based on an output signal of the piezoelectric element and,when the pressure load detected satisfies a standard to provide atactile sensation, to drive the piezoelectric element such that thetactile sensation is provided to an object pressing the touch face. 2.The input apparatus according to claim 1, wherein the piezoelectricelement has one end mounted on the touch sensor and the other endopened.
 3. A control method of an input apparatus including a touchsensor configured to detect a touch input; and a piezoelectric elementmounted on the touch sensor, comprising the step of: detecting apressure load on a touch face of the touch sensor based on an outputsignal of the piezoelectric element and, when the pressure load detectedsatisfies a standard to provide a tactile sensation, driving thepiezoelectric element such that the tactile sensation is provided to anobject pressing the touch face.